Portable detection apparatus and method

ABSTRACT

A portable detection apparatus includes a fluid inlet to acquire a stream of fluid, a fluid outlet and a fluid flowpath therebetween. A pump circulates the fluid through the fluid flowpath. A gamma spectrometer and a mercury analyzer engage the fluid flowpath to analyze and detect radiation emitted by the fluid. A filter trap is in the fluid flowpath downstream from the gamma spectrometer and the mercury analyzer. The filter trap includes a valve assembly and at least a first and second filter for collecting gaseous constituents from the fluid. Each filter is removably connected to the first valve assembly. The valve assembly has a first configuration, in which the first filter is fluidly connected to the fluid flowpath and the second filter is fluidly isolated from the fluid flowpath, and a second configuration, in which the second filter is fluidly connected to the fluid flowpath and the first filter is fluidly isolated from the fluid flowpath.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.15/184,069, filed Jun. 16, 2016 and entitled Portable DetectionApparatus and Method, which itself claims the benefit of 35 USC 119based on the priority of US Provisional Patent Application 62/180,325,filed Jun. 16, 2015 and entitled Portable Detection Apparatus andMethod. The entirety of these applications being incorporated herein inits entirety by reference.

FIELD

The present subject matter of the teachings described herein relatesgenerally to a portable detection apparatus.

BACKGROUND

Environmental monitoring systems can be used in a number ofcircumstances. Accidents involving radiological cargo, unplanneddischarges of contaminants to liquid or air, analysis of radiologicalstorage systems, and remediation and decommission of contaminatedbuildings and areas all may involve analysis of the environment in andaround a location of interest. With off-site laboratory analysis, it maytake up to 6 weeks to ship acquired samples to a laboratory and receiveresults. In this time, conditions may shift leading to potential dangeror further contamination. As well, if it turns out that thecontamination is minimal or non-extant, significant and avoidable delaysmay be incurred.

In such cases, on-site analysis of environmental materials may bepreferable. On-site analysis may minimize or prevent time delays indetermining the potential dangers and environmental impact.

For example, mercuric (Hg) nitrate is used as a catalyst in the medicalisotope production process to ensure consistent Mo-99 targetdissolution. The subsequent high level radiological liquid waste iscemented into stainless steel pails and shipped to waste managementareas for long term storage. The liquid waste may be stored in concretetile holes. These tile holes are often engineered concrete structuressurrounded by compacted soil and shielded with a concrete plug.

At current Mo-99 production rates, approximately 10 kg/yr of Hg incemented waste is placed in storage. Structural degradation of Portlandcement is often expected to occur in 7-20 years (after placement in tilehole), resulting in increased surface area and higher leaching rates.While the bulk of the stored Hg has been found to be stronglyincorporated in the cement (˜80%), there is potential for leaching ofthe Hg into the surrounding environment. As a result, it may bedesirable to have a system to evaluate the potential for and magnitudeof Hg releases during storage.

A portable detection apparatus may be desired to alleviate some of theabove-noted concerns. As well, a compact and portable detectionapparatus capable of analyzing and modelling a variety of contaminantsreleased in fluid form may provide flexibility to monitor differentenvironmental situations.

SUMMARY

This summary is intended to introduce the reader to the more detaileddescription that follows and not to limit or define any claimed or asyet unclaimed invention. One or more inventions may reside in anycombination or sub-combination of the elements or process stepsdisclosed in any part of this document including its claims and figures.

Environmental monitoring systems and apparatus can be used in a varietyof situations to measure levels and emission levels of potentialcontaminants. To properly assess the environmental situation, detectemissions and profile the flow of emissions, it may be necessary tomeasure and analyze acquired fluid samples using a series or sequence ofdifferent techniques and analytical equipment. In some cases, analysisand monitoring equipment may be used at a site only once, for instanceto investigate contamination or emissions from a recent unplannedemission such as caused by an accident, disaster or emergency. It may bebeneficial in such circumstances to have a portable detection apparatuscapable of performing the different measurements and analysis. Aportable detection apparatus could provide relatively rapidly deployablemonitoring and analysis capabilities to respond to emergencies. It mayalso be helpful for the detection apparatus to be modular in nature, toallow for modifications depending on the particular environmentalassessments required.

In accordance with one broad aspect of the teachings disclosed herein, aportable detection apparatus may have an apparatus fluid inlet to drawin a stream of fluid, an apparatus fluid outlet and a fluid flowpathextending therebetween. The apparatus may also have a pump forcirculating the fluid through the fluid flowpath and at least one of agamma spectrometer, positioned to engage the fluid flowpath that isoperable to detect radiation emitted by the fluid while the fluid isflowing through the fluid flowpath, and a mercury analyzer in the fluidflowpath operable to analyze the fluid flowing through the fluidflowpath. The apparatus may further include at least a first filter trapprovided in the fluid flowpath downstream from the gamma spectrometerand the mercury analyzer. The first filter trap may have a first valveassembly and at least a first filter and a second filter for collectinggaseous constituents from the stream of fluid that are removablyconnected to the first valve assembly. The first valve assembly may beconfigurable in a first configuration in which the first filter isfluidly connected to the fluid flowpath and the second filter is fluidlyisolated from the fluid flowpath, and a second configuration in whichthe second filter is fluidly connected to the fluid flowpath and thefirst filter is fluidly isolated from the fluid flowpath.

In some examples, the gamma spectrometer may be upstream from themercury analyzer.

In some examples, the fluid flowpath may have a fluid conduit with aconduit inlet and a conduit outlet downstream from the conduit inlet,and the gamma spectrometer and the mercury analyzer may be between theconduit inlet and the conduit outlet and the first filter trap maybetween the conduit outlet and the apparatus fluid outlet. In someparticular examples, the gamma spectrometer may have a first samplechannel that is sized to removably receive a portion of the fluidconduit, and the gamma spectrometer may be operable to detect ionizingradiation emitted by the fluid while the fluid is flowing through thefirst sample channel.

In some examples, the apparatus may also have a radiation shield atleast partially covering the gamma spectrometer and the sample channelto shield the portion of the fluid conduit received within the samplechannel from background radiation.

In some examples, the gamma spectrometer may have a second samplechannel that is a different size than the first sample channel and isconfigured to receive a portion of a second fluid conduit that has adifferent size than the fluid conduit (i.e. the primary fluid conduit).

In some examples, the apparatus may also have a meteorological stationthat includes at least one of a temperature sensor, a pressure sensor,rain sensor and a wind speed sensor.

In some examples, the apparatus may also have a primary housingcontaining the gamma spectrometer and the mercury analyzer, and a filterhousing that is external the primary housing and contains the firstfilter trap.

In some examples, the apparatus fluid inlet may be external and spacedapart from the primary housing. In some particular examples, theapparatus fluid inlet may be spaced apart from the primary housing by adistance of between about 1 m and 30 m.

In some examples, the primary housing may include the apparatus fluidinlet and the filter housing may include the apparatus fluid outlet.

In some examples, the primary housing may include a primary housingfluid outlet and the filter housing may include a filter housing fluidinlet that is detachably fluidly connectable to the primary housingfluid outlet by a fluid coupling. In some particular examples, thefilter housing may be detachably mounted to the primary housing and whenthe filter housing fluid inlet is detached from the primary housingfluid outlet the filter housing may be detachable from the primaryhousing. In some particular examples, the primary housing may have adoor that is movable between a closed position, in which the primaryhousing is fluidly sealed with the exception of the apparatus fluidinlet and the primary housing fluid outlet, and an open position, inwhich at least one of the gamma spectrometer and the mercury analyzerare accessible.

In some examples, the filter housing may have a body and lid that ismovable between a closed position and an open position, and the firstand second filters may be removable when the lid is in the openposition.

In some examples, the first valve assembly may have a first manifoldwith a first manifold inlet connectable in fluid communication with thefilter housing fluid inlet, a first manifold outlet with a first valveand a second manifold outlet with a second valve, and the first filtermay be connectable to the first manifold outlet and the second filtermay be connectable to the second manifold outlet. In some particularexamples, the first valve and second valve may be operable independentlyof each other.

In some examples, the apparatus may further include a controllerconfigured to receive inputs from the gamma spectrometer and mercuryanalyzer. In some particular examples, the controller may be configuredto generate at least one of plume concentration data and a plume profilemap based on the received inputs.

In some examples, the apparatus may have at least two wheels rollinglysupporting the portable detection apparatus and a coupling forconnecting the portable detection apparatus to a vehicle.

In some examples, the apparatus may have a second filter trap in thefluid flowpath downstream from the gamma spectrometer and the mercuryanalyzer. The second filter trap may include a second valve assembly andat least a third filter and a fourth filter configured for collectinggaseous constituents from the stream of fluid and removably connected tothe second valve assembly. The second valve assembly may be configurablein a first configuration in which the third filter is fluidly connectedto the fluid flowpath and the fourth filter is fluidly isolated from thefluid flowpath, and a second configuration in which the fourth filter isfluidly connected to the fluid flowpath and the third filter is fluidlyisolated from the fluid flowpath. In some particular examples, thesecond filter trap may be fluidly connected in series downstream fromthe first filter trap.

In some particular examples, the apparatus may have a primary housingcontaining the gamma spectrometer and the mercury analyzer, a firstfilter housing containing the first filter trap and a second filterhousing containing the second filter trap, and the first filter housingand second filter housing may be external the primary housing and may bedetachably mounted to the primary housing. In some particular examples,the second filter trap may be fluidly connected in parallel with thefirst filter trap whereby one of the first filter housing and the secondfilter housing can be detached from the primary housing withoutinterrupting the fluid communication between the other of the firstfilter housing and the second filter housing and the primary housing.

In some examples, the apparatus may have at least one on board powersource electrically connected to at least one of the gamma spectrometer,mercury analyzer and filter trap.

In some examples, the portable detection apparatus may have a width in afirst direction and a length in a second direction that is orthogonal tothe first direction, and the width and length may each be less thanabout 5 feet. In some particular examples, the width may be less thanabout 5 feet and the length may be less than about 3 feet.

In some examples, the apparatus may have a particle filter covering theapparatus fluid inlet to filter particulate from the fluid as it entersthe fluid flowpath.

In some examples, the pump may be integral with the mercury analyzer.

In accordance with another broad aspect of the teachings describedherein, which may be used alone or in combination with any otheraspects, a portable detection apparatus may have a sample lineconfigured to receive a flowing fluid and a detector positioned todetect ionizing radiation emitted by the fluid flowing through thesample line. The apparatus may also have a controller linked to thedetector that is operable to trigger the detector at a predeterminedsampling rate while the fluid is flowing through the sample line and aradiation shield at least partially surrounding the sample line and thedetector to shield the detector from background radiation. In someparticular examples, the detector may be a gamma spectrometer.

In accordance with another broad aspect of the teachings describedherein, which may be used alone or in combination with any otheraspects, a method of monitoring fluid contaminations may include drawinga stream of the fluid into a fluid flowpath and analyzing the flowingfluid using at least one flow-through detection apparatus. The methodmay also include capturing a first batch of particulates from the fluidby directing at least a portion of the fluid exiting the flow-throughdetection apparatus to flow through a first filter, isolating the firstfilter from the fluid flowpath, and capturing a second batch ofparticulates from the fluid by directing the at least a portion of thefluid exiting the flow-through detection apparatus to flow through asecond filter. In some particular examples, analyzing the flowing fluidmay include at least one of detecting radiation and collecting mercuryfrom the flowing fluid.

Other aspects and features of the teachings disclosed herein will becomeapparent, to those ordinarily skilled in the art, upon review of thefollowing description of the specific examples of the presentdisclosure.

DRAWINGS

The drawings included herewith are for illustrating various examples ofarticles, methods, and apparatuses of the teaching of the presentspecification and are not intended to limit the scope of what is taughtin any way.

In the drawings:

FIG. 1A is a perspective view of one example of a portable detectionapparatus;

FIG. 1B is another perspective view of one example of the portabledetection apparatus of FIG. 1;

FIG. 2A is another perspective view of one example of the portabledetection apparatus of FIG. 1;

FIG. 2B is a further perspective view of one example of the portabledetection apparatus of FIG. 1;

FIG. 3A is a perspective view of one example of the portable detectionapparatus of FIG. 1 with the primary housing removed;

FIG. 3B is another perspective view of one example of the portabledetection apparatus of FIG. 1 with the primary housing removed;

FIG. 3C is a zoomed in perspective view of a portion of one example ofthe portable detection apparatus of FIG. 1 with the primary housingremoved;

FIG. 4A is a perspective view of one example of the portable detectionapparatus of FIG. 1 with the door of the primary housing open;

FIG. 4B is another perspective view of one example of the portabledetection apparatus of FIG. 1 with the door of the primary housing open;

FIG. 5 is a top view of one example of the portable detection apparatusof FIG. 1 with the lid of the filter housing removed;

FIG. 6A is a perspective view of one example of a filter trap for aportable detection apparatus with the lid open;

FIG. 6B is a top view of the filter trap of FIG. 6A with the lid open;

FIG. 7 is a block diagram of one example of a portable detectionapparatus;

FIG. 8 is a cross-section of an example of a radiation shield for agamma spectrometer that may be used with the portable detectionapparatus of FIG. 1;

FIG. 9 is a flowchart of one example of a method of monitoring fluidcontaminations.

DETAILED DESCRIPTION

Various apparatuses or processes will be described below to provide anexample of an embodiment of each claimed invention. No embodimentdescribed below limits any claimed invention and any claimed inventionmay cover processes or apparatuses that differ from those describedbelow. The claimed inventions are not limited to apparatuses orprocesses having all of the features of any one apparatus or processdescribed below or to features common to multiple or all of theapparatuses described below. It is possible that an apparatus or processdescribed below is not an embodiment of any claimed invention. Anyinvention disclosed in an apparatus or process described below that isnot claimed in this document may be the subject matter of anotherprotective instrument, for example, a continuing patent application, andthe applicants, inventors or owners do not intend to abandon, disclaimor dedicate to the public any such invention by its disclosure in thisdocument.

Emergency response situations involving unplanned releases ofradiological material may require monitoring or analysis. Suchsituations include road accidents involving radiological cargo andunplanned discharges to liquid or air. Environmental remediation anddecommissioning is another example of a situation where environmentalmonitoring systems may be employed.

Analysis of environmental materials may involve an up to 6 weekturnaround time to ship samples to an off-site laboratory and receiveresults. On-site analysis and monitoring of contaminants in air, doseand contaminant dispersion may all be helpful in the aftermath of anunplanned release of radiological material. On-site analysis of thegamma radiation levels of different environmental materials such assoil, sediment, water, vegetation may avoid time delays and costs bydetermining if material is contaminated. If material is uncontaminatedand/or below acceptable limits, it can be put back in place, alsoavoiding cost of disposition of waste. If material is contaminated, itcan then be shipped to a laboratory for further analysis if desired.Furthermore, continuous monitoring of particulate, gases in air, and/orliquids may be desirable during remediation and decommissioning ofcontaminated buildings or areas. To help facilitate measurement andmonitoring of fluid contaminations in a target location the inventorshave developed a portable detection apparatus.

Optionally, the detection apparatus may include a sample line or fluidinlet to draw in or receive a flowing fluid, such as air or water. Thedetection apparatus may include one or more detectors positioned toanalyze the fluid, including, for example, when the flowing through thesample line. Optionally, the detectors may include flow-through typedetectors that are capable of analyzing the fluid in real time, i.e. asit flows through the sample line. Optionally, the detectors can also beconfigured to output data in real time, or may be configured to collectand store the data locally and only output the data at pre-determineintervals and/or when queried by a user, controller or other part of thedetection apparatus. Alternatively, or in addition to the flow-throughtype detectors, the detection apparatus may include at least oneoff-line or static type detector that is configured to analyze a static,non-flowing fluid.

The detectors may be any detector that is suitable for detectingtargeted contaminant in a particular environment. For example, ifradioactive materials are expected to be present in the samplingenvironment, the detection apparatus may include a radiation detectorsuch as, for example, a gamma spectrometer. If mercury is expected to bepresent, the detection apparatus may also include a mercury analyzer.Optionally, some or all of the detectors may be modular and may beremovably connected to the detection apparatus. This may allow differentcombinations of detectors to be selected based on the environment inwhich the detection apparatus is to be deployed, and/or to targetspecific contaminants.

Optionally, the detection apparatus may also include one or more filtertraps for collecting particles and/or gaseous constituents from theacquired stream of fluid. Preferably, the filter traps are placeddownstream of the flow-through detectors so as not to compromise themeasurements from those detectors, for example by filtering out theparticles and/or gaseous constituents that are to be detected by thedetectors. Each filter trap may include a plurality of individualfilters that may optionally be removably connected to a valve assembly.The valve assembly can have a number of different configurations and maybe used to regulate the flow of the fluid and to direct the stream offluid through the filters. Optionally, the valve assembly can beconfigured to route the fluid stream through on filter at a time.Alternatively, the valve assembly may be operable to divide the fluidstream between two or more filters in parallel. The filter traps neednot be configured to provide real time analysis. Instead, using thevalve assembly, the fluid may be routed through a given filter for apre-determined period of time. The filter can then be analyzed off-line,and optionally removed from the detection apparatus and analyzed in aremote location such as a laboratory. Optionally, the data from thefilters can be co-related with the data from the flow-through detectors.For example, data from the flow-through detectors from a specific periodof time can be associated with the contents of one or more filters thatwere receiving the fluid flow during the same time period.

The portable detection apparatus may also include other associatedmonitoring sensors and equipment, including, for example combustible gasmonitors (suitable for monitoring CH₄, CO₂, CO, H₄S, SO₂, NO, H₂, O₂);high volume air samplers (operable to collect data on total suspendedparticulates in air—optionally both total and active particles) UltraViolet radiation light sensors (UVA/UVC radiation light sensors); doesrate meters and detectors; flow meters; flux chambers; wirelesstemperature, humidity, and barometric pressure probes; rain gauges(optionally an optical rain gauge); a meteorological tower; and samplingchambers to conduct radiological measurements on other environmentalmedia (e.g. vegetation, soil, sediment, water).

The portable detection apparatus may also include one or morecontrollers for controlling the operation of the various detectors,filter traps and other equipment, and/or for collecting an processingthe data collected. Optionally, the controllers may include one or moreprocessors, a storage module, a communication module (including areceiver and a transmitter), a user output device and any other suitablecomponents. The controller may interface with the detectors and filtersto adjust calibration and operational parameters, as well as to receivemeasurement and analysis data. Optionally, the controller may beprovided with software to enable the controller to generate an fluiddispersion model, for example, in the form of a plume profile, to modelhow fluid contaminants have dispersed within the surrounding environmentand/or predict the future dispersion of the contaminants, based on thedetected contaminant concentrations, and properties and the current andpast meteorological conditions.

Optionally, the meteorological tower or weather station, and any of theother equipment provided on the detection apparatus, can also supplydata to the controller that can be used in the generation of the plumeprofile model. The controller may also be configured to receive datafrom remote sources (such as a network storage device, meteorologicaldata from other locations, facility monitoring devices, otherenvironmental sensors, etc.) and use this data to help generate theplume model. The model may generate an estimate of emission rate for acontaminant source, and optionally may then provide a map ofconcentrations and doses over a given area from a known or suspectedcontaminant source. The model may be used to locate the most effectivelocations to sample, as well as to infer the location of an emissionsource given the location of sample uptake and the wind speed. Forexample, the behavior of mercury contaminant released into the air tendsto be influenced by temperature and solar radiation. To help improve theaccuracy of the mercury dispersion model the portable detectionapparatus may include probes to continuously measure temperature,pressure and humidity and provide the data to the controller (optionallywirelessly, for example using remote sensors that are up to 90 m awayfrom the detection apparatus) as well as a UVA/UVC meter. Aprecipitation sensor, such as an optical rain gauge, may also be used toestimate precipitation levels and/or wet and dry deposition and providethis data to the controller.

Reference will now be made to FIGS. 1A and 1B. FIG. 1A shows aperspective view of a portable detection apparatus 10 from the top,front and left hand side. FIG. 1B shows a perspective view of portabledetection apparatus 10 from the top, back and left hand side. In theillustrated example, the portable detection apparatus 10 is configuredas a portable trailer that can be transported to a variety of differentanalysis/detection locations, for example by pulling the trailer with avehicle or by maneuvering the trailer by hand.

In the illustrated example, the portable detection apparatus 10 can beused to monitor and analyze fluid contaminations and emissions in thesurrounding environment by drawing a portion of the surrounding air intothe apparatus 10 for analysis. Specifically, the apparatus 10 includesan apparatus fluid inlet 30 used to draw in a stream of fluid and anapparatus fluid outlet 32. The stream of fluid may be received by, andflow through, a sample line or fluid flowpath. In some examples, aparticle filter may cover the apparatus fluid inlet 30 to help filterunwanted particulate from the fluid as it enters the fluid flowpath.This may help reduce fouling of the detectors and other equipment incommunication with the fluid flow path.

The portable detection apparatus 10 also includes an apparatus fluidoutlet that is preferably downstream from the detectors, filters andother sampling equipment, and is fluidly connected to the fluid inlet 30via the fluid flowpath. Optionally, one or more flow-through detectorsmay be positioned along the sample line or fluid flowpath to analyze theacquired stream of fluid. For instance, the flow-through detectors mayinclude at least one of a gamma spectrometer and a mercury analyzer. Inthe present example the inventors have adapted a FALCON® 5000 gammaspectrometer manufactured by Canberra Industries Inc to operate as aflow-through gamma spectrometer that is suitable for use in the portabledetection apparatus 10. Specifically, the FALCON® 5000 is modified fromits standard specifications by modifying the gamma spectrometry softwareto allow for repeated measurements over a pre-determined time periodwhile the fluid flows past the detector. One example of a suitablemercury analyzer is the TEKRAN® 2537B Continuous Hg Vapour Analyzer,manufactured by Tekran Instruments Corporation.

The flow-through detectors (i.e. gamma spectrometer, mercury analyzerand other detectors) may be contained within primary housing 12. Theflow-through detectors may be configured to receive the fluid directly(i.e. be in direct contact with the fluid as part of the air flow path),or alternatively may be configured to analyze the fluid while it remainswithin the sample line (such as by observing and/or sensing the fluidthrough the sidewalls of the sampling line).

Optionally, the portable detection apparatus 10 may include a singleouter shell or housing that contains the detectors, filters and otherequipment. The housing may be configured to be generallyweather-resistant to help protect the internal equipment from rain,snow, wind and other environmental factors. Optionally, the housing maybe sealed so that it is substantially water-tight and/or substantiallyair-tight, with the exception of the fluid inlet and outlets (and otherinstrumentation ports and/or access points as required). The housing mayalso be configured to help secure the equipment and protect it fromtampering and/or theft. For example, the housing may be made from arelatively strong material, such as metal or plastic, and may include alocking mechanism or other apparatus to help prevent unauthorized accessinto the interior of the portable detection apparatus. This may helpprotect the equipment if the portable detection apparatus is leftunattended in a monitoring location.

Alternatively, instead of a single housing or outer shell, the portabledetection apparatus may include two or more housings, each containingsome of the equipment. Providing separating housings may allow theproperties of each housing to be tailored to its function and/or to theequipment within the housing. For example, one housing may be made frommetal while another is made from plastic. Optionally, the housings maybe individually sealed so that the interior of one housing is generallyisolated from the interior of another housing. This may help reduce thechances of cross-contamination between the housings. For example, ifthere is a fluid leak within the interior of one housing, the equipmentin a separate, isolated housing may not be affected. Providing separatehousings may also help facilitate the modular aspect of the portabledetection apparatus design, as individual housings may be added orremoved from the apparatus to modify its scale and/or capabilities. Someof the housings may be detachably connected to each other. For example,a housing containing the filter trap equipment may be detachable from ahousing that contains the flow-through detectors. This may allow thefilter traps to be removed or replaced (for example to take the filtersto a testing location) without disturbing the flow-through detectors.Optionally, some or all of the housings may be radioactively shielded.This may help protect some equipment, such as the controller, fromradiation that is present in other portions of the portable detectionapparatus, such as proximate the gamma spectrometer or filters.

Referring to FIGS. 1A and 1B, in the illustrated example the portabledetection apparatus 10 includes primary housing 12 and two separatefilter housings 14 that are external and isolated from the primaryhousing 12 (a different number of filter housings may be used ondifferent embodiments of a detection apparatus). Filter housings 14 areprovided in the form of separate, brief-case type enclosures that aredetachably secured to primary housing 12. In the illustrated example, adetachable filter housing attachment member in the form of an adjustablestrap 26 is used to detachably secure the filter housings 14 to theprimary housing 12. When filter housing 14 is in place on top of primaryhousing 12, the strap 26 can be attached to anchors on the top or sidesof primary housing 12. The strap 26 can then be tightened to securefilter housing 14 to primary housing 12. Additional attachmentmechanisms may also be used, such as guides on the surface of primaryhousing 12 to prevent lateral displacement of filter housing 14.Providing a releasable strap 26 may allow each filter housing 14 to beseparated from the primary housing 12 and replaced with replacementfilter housing. This may help facilitate quick changes of the filterstrap equipment, wherein a user can quickly swap a new filter housing 14for a used filter housing 14 without having to individually deal withall of the internal filters, etc. Providing a quick change mechanism mayhelp reduce the amount of time a user needs to spend in the field withthe portable detection apparatus 10, which may be beneficial if the areais unpleasant or dangerous (i.e. radioactively contaminated, cold, hot,etc.).

Filter housings 14 may each contain at least one first trap. In somecases, a first filter trap 20 and a second filter trap 22 may be used.The filter traps can be used to trap contaminants contained with theacquired stream of fluid. The filter traps are positioned downstream ofthe flow-through detectors so that analysis of the fluid by theflow-through detectors is not adversely affected when contaminants areremoved from the fluid by the filter traps.

Referring to FIG. 6A, each filter housing 14 has a housing body 40 and alid 24. Lid 24 can transition between an open position and a closedposition. In the open position, access is provided to filter traps 20and 22 and the filters 82 and 84 therein can be removable. In the closedposition, the lid 24 and housing body 40 can provide a waterproof seal,to prevent contamination of filter traps 20 and 22. Optionally, the lid24 (or other portion of the filter housing 14) may be transparent. Thismay allow a user to inspect the interior of the filter housing 14without having to open the lid 24.

In the illustrated example, the filter housings 14 can be ruggedwaterproof cases that lie on top of primary housing 12 and have exteriordimensions of about 79.5 cm×51.8 cm×31.0 cm. There may also beadditional shielding material on top of the primary housing 12 orincorporated into the filter housing 14. This may be useful if thefilters are expected to capture radioactive materials.

The shielding material may be any suitable material, includingtungsten-impregnated, silicone pieces such as Tungsten Siflex. In somecases, the additional shielding material may be about ⅛″ thick. Theshielding effectiveness of the additional shielding material may beabout 21% for Cs-137 and about 12% for Co-60. The half-value layer (HVL)of the additional shielding material may be about 0.92 cm (0.36″) forCs-137 while for Co-60 the HVL may be about 1.60 cm (0.63″).

Referring again to FIGS. 1A and 1B, the fluid inlet 30 may be containedwithin primary housing 12. Alternatively, apparatus fluid inlet 30 maybe external and spaced apart from primary housing 12. For instance,apparatus fluid inlet 30 may be spaced apart from primary housing 12 bya distance of between about 1 m and 30 m or more. This may allow thefluid inlet location to be spaced apart from the primary housing 12.This may allow a stream of fluid to be acquired from a position closerto a target source while placing the apparatus 10 farther from thesource to reduce the likelihood of contamination. This may also allowthe fluid inlet 30 to be directly connected to fluid source, such as apipe, smoke stack, existing fluid monitoring systems and otherapparatuses.

Preferably, the fluid inlet 30 is fluidly coupled to a fluid hose orconduit that forms the sampling line carrying the acquired stream offluid to through primary housing 12, and the detectors housed therein.The sampling line may be rigid or flexible (or both in differentregions) and may be of any suitable diameter.

Apparatus fluid outlet 32 may allow the stream of fluid to be releasedafter passing through the flow-through detectors and filter traps. Insome cases, apparatus fluid outlet 32 may be contained within the filterhousing 14. Apparatus fluid outlet 32 may be coupled to a fluid hose orconduit that releases the stream of fluid downwind and/or downstream ofthe target source to reduce the risk of contamination of the apparatus10.

Referring to FIGS. 2B and 5, in the illustrated example the samplingline is providing in the form of a flexible hose that has a conduitinlet 34 and a conduit outlet 36 downstream from conduit inlet 34. Theflow-through detectors such as the gamma spectrometer and the mercuryanalyzer can be positioned between conduit inlet 34 and conduit outlet36. Filter traps 20 and 22 may be positioned after the conduit outlet36, and between conduit outlet 36 and apparatus fluid outlet 32.

When the flow-through detectors are contained with primary housing 12,conduit inlet 34 may also be referred to as a primary housing inlet andconduit outlet 36 may also be referred to as the primary housing outlet.The filter housing 14 may include a filter housing fluid inlet 42 thatis detachably fluidly connectable to the primary housing fluid outlet 36by fluid coupling 98 (FIG. 1A). This may allow the filter housing 14 tobe detachable from primary housing 12, when the filter housing fluidinlet 42 is detached from primary housing fluid outlet 36 by detachingfluid coupling 98.

Detachably mounting filter housings 14 to primary housing 12 may allowfilter housing 14, and thereby filter traps 20 and 22 to be removed forpurposes of analysis, maintenance, or transport. This may also allowdifferent types of filter housings and filter traps to be used withapparatus 10 depending on the particular environmental monitoringrequired (e.g. depending on the particular contaminants being modelledor evaluated).

When multiple filter traps, such as filter traps 20 and 22, are used,they can each be fluidly coupled to the fluid flowpath at a positiondownstream from the flow-through detectors. In some examples, secondfilter trap 22 may be fluidly connected in series downstream from firstfilter trap 20, for instance using fluid coupling 28 (FIG. 1B). Thefirst filter trap 20 may have a first filter trap outlet 44, while thesecond filter trap 22 has a second filter trap outlet 46 (FIG. 5). Eachof the first filter trap outlet 44 and the second filter trap outlet 46can be fluidly connected to apparatus fluid outlet 32 to allow thestream of fluid to be released after passing through at least one of thefilter traps 20, 22.

Alternatively, in some other examples, the first and second filter traps20, 22 can be fluidly connected in parallel. This may allow the filterhousing 14 for one of the first filter trap 20 and the second filtertrap 22 to be detached from primary housing 12 without interrupting thefluid communication between the other fluid housing 14 and primaryhousing 12.

Referring again to FIGS. 1A and 1B, in the illustrated example theprimary housing 12 is mounted on a portable chassis 38, and the filterhousings 14 are mounted to the primary housing 12. The chassis 38 isconfigured as a trailer and includes two wheels to 16 rollinglysupporting the portable detection apparatus 10. Chassis 38 may alsoinclude a coupling 18, such as a hitch for connecting the portabledetection apparatus 10 to a vehicle. For instance, chassis 38 may be aroad-licensed one-axle trailer that can be towed behind a vehicle suchas a car, truck or all-terrain vehicle. This may allow apparatus 10 tobe easily moved between sampling locations as desired. Once apparatus 10has reached its desired location for environmental monitoring, stands 54can be used to maintain apparatus 10 in an upright position afterchassis 38 is detached from the vehicle. In other embodiments thechassis may have a different configuration (more wheels, differentdimensions, etc.).

In the illustrated example, the detection apparatus 10 includes ameteorological station or weather sensing unit 74 that is positioned onthe top of an extendable or telescoping pole 52. Pole 52 can be extendedso that sensing unit 74 is positioned at a greater height when inoperation to more accurately obtain meteorological measurements. Sensingunit 74 may include multiple meteorological sensors and an integratedglobal navigation satellite system (GNSS) such as the global positioningsystem (GPS) so as to obtain a plurality of measurements in bothstationary and moving conditions. The meteorological station 74 may alsoinclude at least one of a temperature sensor, a pressure sensor, a rainsensor, and a wind speed sensor. The meteorological station 74 may beconfigured to measure a variety of variables, including apparent windspeed, apparent wind direction, magnetic compass heading, airtemperature, relative humidity, dew point temperature, wind chilltemperature, barometric pressure, true wind speed, true wind direction,heading relative to true north, true wind chill temperature. Thisinformation can be provided to the detection apparatus controller, andmay be used to model atmospheric dispersion of one or more contaminants.An atmospheric plume profile model may be used to model the dispersionof the contaminants. The emission data obtained from the flow-throughdetectors and filter traps of apparatus 10 can then be used toback-calculate the emission rate from the target source.

Optionally, the portable apparatus 10 may have a relatively compactfootprint. This may allow the detection apparatus 10 to be driven onroads and may enable it to be deployed in difficult to access locationsor within buildings. Optionally, the overall width of the detectionapparatus 10 may be selected so that the detection apparatus 10 can passthrough a standard, double-door way in a building. This may helpfacilitate placing the detection apparatus 10 apparatus withinbuildings. Referring to FIG. 2A, the detection apparatus 10 may have awidth 11 in a first direction and a length 13 in a second directionorthogonal to the first direction. The primary housing may have the samewidth as the detection apparatus 10 (i.e. width 11), and may have ashorter length 15. Preferably, the width 11 is less than about 5 feet,and optionally the length 13 may also be less than about 5 feet. Theprimary housing 12 may have a width can be less than about 5 feet andthe length 15 can be less than about 3 feet.

Referring to FIG. 1A, the height 17 of apparatus 10 may be variabledepending on whether telescopic pole 52 is used. For instance, thedetection apparatus 10 may have a height 17 of about 175 cm withouttelescopic pole 52, while the detection apparatus 10 may have a heightof about 267 cm when telescopic pole 52 is employed and extended.Providing a telescopic pole 52 may allow the pole 52 to be retractedwhen the detection apparatus 10 is in transport, and then extended whenthe detection apparatus 10 reaches the monitoring location. In someexamples, primary housing 12 may have an internal compartment size ofabout 94 cm³, but may be configured to be larger or smaller based onparticular equipment selections and/or expected uses of the apparatus10.

Optionally, the primary housing 12 may also include a heater, an airconditioning unit, heat pump or other suitable climate control mechanismto control the temperature within primary housing 12. This may behelpful in stabilizing the operating conditions for the flow-throughdetectors such as the gamma spectrometer and the mercury analyzer whenapparatus 10 is deployed for sampling. For example, it may be desirableto keep the interior of the apparatus 10 at a different temperature thanthe surrounding environment. Optionally, when in operation, it may bedesirable to erect a temporary shelter, such as a tent or other suchshelter, around apparatus 10 to provide shade and potentially reduce theworkload for the air conditioner.

Preferably, the apparatus 10 can be configured to have a total weightthat is low enough to allow the apparatus 10 to be transported onstandard roadways, and optionally so that the apparatus can be movedacross unpaved surfaces (such as gravel or dirt roads, off road, etc.)to a desired monitoring location. It may also be preferable in someconfigurations to configure the apparatus 10 to have a weight that islow enough so that a single user, or possible two or more users, canmanually roll the apparatus 10 across a surface without the need for avehicle or other powered assistance. This may help users maneuver theapparatus 10 into a variety of monitoring locations which may beotherwise inaccessible using larger and/or heavier apparatuses. Forexample, the total weight of the apparatus 10 may be less than 2000 Kg,and optionally may be less than about 1000 Kg, less than about 750 Kg orless than about 500 Kg. In the illustrated configuration, the totalweight of apparatus 10, including the primary housing 12, filterhousings 14 and their contents is about 565 kg.

Reference will now be made to FIGS. 2A-2B. FIG. 2A is a perspective viewof portable detection apparatus 10 from the top, back and left hand sidesimilar to FIG. 1B, but the walls of primary housing 12 and filterhousing lid 24 are shown as being transparent. FIG. 2B is anotherperspective view of portable detection apparatus 10 from the bottom,left and front where again the walls of primary housing 12 are shown asbeing transparent.

Primary housing 12 may also include a door 56. Door 56 may be movablebetween a closed position (FIGS. 1A and 1B) and an open position (anexample of which is shown in FIGS. 4A-4B. In the closed position,primary housing 12 may be fluidly sealed with the exception of apparatusfluid inlet 30 and primary housing fluid outlet 36. In the openposition, at least one of gamma spectrometer 76 and mercury analyzer 72may be accessible. This may provide access for maintenance, orcalibration, or other adjustments to gamma spectrometer 76 and/ormercury analyzer 72.

Reference will now be made to FIGS. 4A-4B, shown therein is portabledetection apparatus 10 with the door 56 of primary housing 12 in theopen position. FIG. 4A shows a perspective view from the back, left andtop, while FIG. 4B shows a perspective view from the back, right andtop.

With the door 56 in the open position, an operator can access gammaspectrometer 76 and mercury analyzer 72, as well as other componentscontained within primary housing 12. For instance, primary housing 12generally includes at least one controller or processor that regulatesand controls the operation of the components such as gamma spectrometer76, mercury analyzer 72 and filter traps 20, 22. For instance, thecontroller may control the operation of the valve assemblies in filtertraps 20, 22.

Door 56 may include a handle 58 to allow an operator to easilytransition door 56 between the open position and the closed position. Insome cases, door 56 may also include a lock to secure apparatus 10 inthe closed position. This may provide some security for apparatus 10when left unattended at a sampling location.

As shown in FIG. 2, in the illustrated example the primary housing 12houses gamma spectrometer 76 and mercury analyzer 72. In some examples,the apparatus 10 may include a pump or other suitable apparatus forcirculating fluid through the fluid flowpath. In the illustratedexample, is an integral component of the TEKRAN mercury analyzer 72. Thepump may be integral with mercury analyzer 72. In other cases, aseparate pump may be used to circulate the fluid through the fluidflowpath.

Primary housing 12 may also include a gas supply container 90. Container90 may contain an inert gas such as argon for use as a carrier fluid bymercury analyzer 72. Mercury analyzer 72 may require a substantiallyconstant, or regulated, flow of gas. Accordingly, a regulator 62 may befluidly connected between container 90 and mercury analyzer 72 tocontrol the flow of carrier gas therebetween.

In some cases, primary housing fluid outlet 36 may also include reliefoutlets 50 and 68. Relief valve outlets 50 and 68 may be used to ventfluid from the fluid flowpath in the event of malfunctions along thefluid flowpath or sample line. Relief outlets 50 and 68 may be fluidlycoupled to pressure relief valves operable to vent fluid in the event ofa pressure build-up.

Reference will now be made to FIGS. 3A-3C, in which the detectionapparatus 10 is shown with the primary housing 12 and filter traps 14removed to reveal the underlying portions of the apparatus 10. FIG. 3Ashows a perspective view from the front, left and top while FIG. 3Bshows a perspective view from the back, left and top. FIG. 3C shows azoomed in perspective view of a portion of portable detection apparatus10 from the front, right and top.

FIGS. 3A-3C illustrate example components of portable detectionapparatus 10 with primary housing 12 and filter housings 14 removed.Apparatus fluid inlet 30 acquires a stream of fluid into the fluidconduit or sampling line. The fluid conduit enters apparatus 10 and runsover gamma spectrometer 76, which is positioned to engage the fluidflowpath or sample line. Gamma spectrometer 76 is operable to detectradiation or ionizing radiation emitted by the fluid while the fluid isflowing through the fluid flowpath.

The fluid conduit may be held on the top of gamma spectrometer 76 by acontainment device that includes at least one sample channel (i.e.containment geometry) to receive a portion of the fluid conduit/sampleline. Securing the sample line within the sample channel may help securethe sample line in the preferred location for measurements. Optionally,more than one sample channel may be provided for use with the gammaspectrometer 76. The sample channels may be interchangeable, and eachsample channel may be configured to receive a specific size or type ofsample line, or other conduit. For example, the gamma spectrometer 76may also include a second sample channel. The second sample channel maybe a different size from the first sample channel and may receive aportion of a second fluid conduit that has a different size than thefluid conduit received by the first sample channel.

Gamma spectrometer 76 may be operable to detect ionizing radiationemitted by the fluid while the fluid is flowing through the first samplechannel. In some examples, apparatus 10 may also include a radiationshield 92 at least partially covering or surrounding the gammaspectrometer 76, the sample channel and the portion of the fluid conduitreceived within the sample channel from background radiation. This mayhelp reduce background radiation levels in the sample channel and mayhelp facilitate obtaining real-time radiation measurements on a flowingfluid. An example of radiation shield is shown in FIG. 8. In some cases,the radiation shielding around gamma spectrometer 76 may also includeadditional radiation shield 78.

Gamma spectrometer 76 may be configured to continuously sample the fluidflowing through the fluid conduit. Gamma spectrometer may continuouslyidentify and quantity radionuclides passing through the fluid flowpathor sampling line. Generally, gamma spectrometer 76 may be any variety ofinstrument that can be used to detect ionizing radiation, such as gammaradiation. For example, a portable high purity germanium basedradionuclide identifier may be used. The gamma spectrometer may have anenergy range from 20 KeV to 2.0 MeV. In some cases, gamma spectrometer76 may also include at least one battery.

Gamma spectrometer 76 is generally configured to identify radiologicalisotopes present in the fluid. In some examples, gamma spectrometer 76may also include a dose rate monitoring device configured to monitor thedose rate of the ionizing radiation in the fluid. For example, the doserate monitoring device may be a Geiger-Müller tube that allows the doserate to be continuously monitored.

Gamma spectrometer 76 may be configured to communicate with a controllercontained within primary housing 12. Optionally, or in addition, thegamma spectrometer 76 may include a wireless communication module toallow wireless communication with the controller or any other computerdevice with wireless range. In some cases, apparatus 10 may also includean additional gamma dose rate meter. The additional gamma dose ratemeter may be used to continuously monitor the background radiation forthe gamma spectrometer 76. The additional gamma dose rate meter may alsobe used to optimize the position of trailer during sampling.

Typically during operation of the apparatus 10 the gamma spectrometer 76is not directly exposed to the fluid flow, or the contaminants therein.This may help reduce the chance of gamma spectrometer 76 becomingcontaminated during active sampling.

Mercury analyzer 72 may also be provided in the fluid flowpath to engagethe sampling line and analyze the fluid flowing through the fluidflowpath. In some cases, the gamma spectrometer 76 is upstream from themercury analyzer 72. In such cases, after the fluid has passed throughthe portion of the fluid flowpath sampled by gamma spectrometer 76, thefluid will then pass to mercury analyzer 72. The fluid may enter asample air inlet of mercury analyzer 72. Alternatively, the mercuryanalyzer 72 may be upstream from the gamma spectrometer 76.

In some examples, mercury analyzer 72 may be configured for radioactivesampling. In other examples, mercury analyzer 72 may be configured fornon-active sampling. Mercury analyzer 72 may also be communicativelycoupled to the controller housed within primary housing 12, or othersuitable controller. This may allow the sample collection period formercury analyzer 72 to be adjusted as desired. For example, mercuryanalyzer 72 may employ 2.5 or 5 minute sample collection periods, where1 litre per minute of fluid is sampled. In some cases, mercury analyzer72 may have a detection limit of 0.01 hg/m³. After the fluid exitsmercury analyzer 72 it may pass through fluid conduit outlet 36 tofilter housing inlet 42, where contaminants may be trapped using filtertraps such as filter traps 20 and 22.

In some cases, mercury analyzer 72 may include an integral pump. Thepump may be used to circulate fluid through the fluid flowpath ofapparatus 10. Mercury analyzer 72 may have a pump exhaust port, whichmay operate as the fluid conduit outlet 36. In the illustrated example,the integral pump within the mercury analyzer 72 is the only pump usedto move fluid through the sample line. In other examples, additionalpumps may be provided in addition to, or in place of, the pump withinthe mercury analyzer 72.

Portable detection apparatus 10 may be modular. As a result, in someexamples, portable detection apparatus 10 may also include additionalsensors as required. For example, one or more gas monitors may beincluded in apparatus 10 for personal, area, or remote sensing. The gasmonitors may be configured to monitor levels of combustible gases suchas CH4, CO2, CO, H2S, SO2, NO, H2, and O2 for example. Additionalsensors may also include a high-volume continuous air sampler forsuspended particulate measurements.

The additional sensors may include a plurality of sensors related tometeorological conditions such as wireless temperature, humidity, andbarometric pressure probe and UVA/UVC sensors. The additional sensorsmay further include a dynamic flux chamber to measure evasion orvolatilization from ground or surface water.

Apparatus 10 may also include a flow meter coupled to the fluid flowpathor sample line. The flow meter can be used to calibrate the flow-ratethrough the fluid flowpath.

Apparatus 10 may also include at least one on board power sourceelectrically connected to the gamma spectrometer 76, mercury analyzer 72and filter traps 20, 22, and/or any of the other onboard equipment. Insome examples, apparatus 10 may include a standalone power source suchas one or more batteries or a generator (e.g. a gasoline generator suchas a Honda 3000™ generator) for remote applications.

Apparatus 10 may also include pressure relief valves to help protectapparatus 10 from over-pressure situations. A first pressure reliefvalve 60 may be located in the fluid flowpath after gas cylinder 90. Thefirst pressure relief valve 60 may discharge if there is anover-pressure between gas cylinder 90 and mercury analyzer 72. Firstpressure relief valve 60 may be fluidly connected to first relief outlet50 to allow the fluid to be discharged into the atmosphere, external toprimary housing 12.

A second pressure relief valve may be located between mercury analyzer72 and filter housings 14. The second pressure relief valve may beconfigured to release if one of the valves in the valve assembly offilter housings 14 fails.

Primary housing 12 also generally includes at least one storage mediumcoupled to the controller. The controller may receive data or such asmeasurements or status information from gamma spectrometer 76, mercuryanalyzer 72, filter traps 20, 22 and/or sensing unit 74. Such data canthen be stored in the storage medium for later analysis or retrieval.For example, the controller may store the mercury concentration of thefluid detected by mercury analyzer 72, the isotope and dose datadetected by gamma spectrometer 76 and the current filter 80 that isbeing sampled in filter traps 20 and 22.

Referring to FIGS. 5, 6A-6B the portable detection apparatus 10preferably includes at least one filter trap, such as first filter trap20. First filter trap 20 includes a plurality of filters 80 including atleast a first filter 82 and a second filter 84. First filter 82 andsecond filter 84 can be used for collecting gaseous constituents fromthe acquired stream of fluid.

The filters 80 (including filters 82 and 84) may be any suitable filterthat is capable of trapping a desired and/or suspected contaminant. Thefirst filter trap 20 also includes a first valve assembly 86. Eachfilter 80 including first filter 82 and second filter 84 can beremovably connected to first valve assembly 86. First valve assembly 86may control the flow of the acquired fluid stream through first filtertrap 20.

Apparatus 10 may also include or more additional filter traps, which canbe connected in series and/or in parallel with each other in the airflowpath. In the illustrated example, the apparatus includes a second filtertrap 22 in addition to the first filter trap 20. In the illustratedexample, the second filter trap 22 is fluidly connected in series with,and downstream of, first filter trap 20. Second filter trap 22 alsoincludes a plurality of filters including at least a third filter 94 anda fourth filter 96. Second filter trap 22 includes a second valveassembly 88 for controlling the flow of the acquired fluid streamthrough the second filter trap, and distributing the flow of fluidthrough the filters. Further details of the configuration and operationof the filter traps, filters and valve assemblies will be discussedbelow with reference to FIGS. 5, 6A-6B.

FIG. 5 shows a top view of portable detection apparatus 10 with the lids24 removed from filter traps 14. FIGS. 6A-6B show examples of the firstfilter trap 20. FIG. 6A shows a perspective view of first filter trap20, while FIG. 6B shows a top view of filter trap 20.

The filter traps provided with examples of portable detection apparatus10 can be configured to capture contaminants in the fluid acquired usingfluid inlet 30. The filter traps are positioned downstream of theflow-through detectors of apparatus 10 so that the capture ofcontaminants does not affect the measurements performed by theflow-through detectors. Each filter trap includes a plurality of filters80. Each filter can be used to collect gaseous constituents from theacquired stream of fluid.

Filter housing inlet 42 can be fluidly connected to primary housing orconduit outlet 36. The fluid connection may be made using detachablefluid connector 98. This allows the filter traps to be detached fromprimary housing 12 if desired. Filter housing inlet 42 is fluidlyconnected to first filter trap 20.

First filter trap 20 includes a first valve assembly 86 and at least afirst filter 82 and a second filter 84. Each filter in first filter trap20 is removably connected to first valve assembly 86. The path taken bythe stream of fluid through first filter trap 20 can be controlled byadjusting the configuration of first valve assembly 86. First valveassembly 86 may be configurable in a first configuration, in which thefirst filter 82 is fluidly connected to the fluid flowpath and thesecond filter 84 is fluidly isolated from the fluid flowpath, and asecond configuration, in which the second filter 84 is fluidly connectedto the fluid flowpath and the first filter 82 is fluidly isolated fromthe fluid flowpath. In either configuration, the stream of fluid passesthrough the filter 80 that is fluidly connected to the fluid flowpathand out first filter trap outlet 44.

First valve assembly 86 may be a manifold valve assembly. First valveassembly 86 may have a first manifold inlet 100 connectable in fluidcommunication with filter housing fluid inlet 42. First valve assembly86 may also include a first manifold outlet 102 having a first valve 106and a second manifold outlet 104 having a second valve 108. First valveassembly may include a plurality of additional manifold outlets andcorresponding valves, such as the eight manifold valve assembly 86 shownhere. First filter 82 may be removably connectable to first manifoldoutlet 102 and second filer 84 may be removably connectable to secondmanifold outlet 104. Each of the first valve 106 and second valve 108may be operable independently.

Second filter trap 22 includes a second valve assembly 88 and at least athird filter 94 and a fourth filter 96. Each filter in second filtertrap 2 is removably connected to second valve assembly 88. The pathtaken by the stream of fluid through second filter trap 22 can becontrolled by adjusting the configuration of second valve assembly 88.Second valve assembly 88 may be configurable in a first configuration,in which the third filter 94 is fluidly connected to the fluid flowpathand the fourth filter 96 is fluidly isolated from the fluid flowpath,and a second configuration, in which the fourth filter 96 is fluidlyconnected to the fluid flowpath and the third filter 94 is fluidlyisolated from the fluid flowpath. In some examples, second valveassembly 88 may be generally of the same construction as first valveassembly 86.

Each of first filter trap 22 and second filter trap 22 may becommunicatively coupled to the controller container in primary housing12. The controller may control the configuration of first valve assembly86 and second valve assembly 88 to control which filter 80 is currentlycapturing gaseous constituents from the stream of fluid. The controllermay operate each of the valves in first valve assembly 86 and secondvalve assembly 88 independently of each other.

The controller may adjust the valve positions for first valve assembly86 and second valve assembly 88 so that only a single filter samplingthe fluid stream at a single time. Each filter 80 may be used to samplethe fluid for a specific time period, such as four hours for example.After the time period has elapsed, the valve positions may be adjustedso that a subsequent filter 80 samples the fluid stream. As such,analysis of the filters 80 may indicate changes in the gaseousconstituents in a time-lapsed manner.

As mentioned above, each filter 80 is removably connected to the valveassemble of the corresponding filter trap. This allows the filters to beeasily removed after sampling is complete and for new filters to beinserted as desired. Once sampling is complete, a filter 80 can beremoved from filter housing 14 using quick disconnect fittings 110. Thefilter 80 can then be sent for regeneration and analysis.

The filter traps can be installed in parallel and the valve assembliesof the filter traps can be controlled by the controller to provide acontinuous single path for the sampled air. The valve position of eachvalve in the filter traps can be recorded alongside the data receivedfrom the detectors such as mercury analyzer 72 and gamma spectrometer76. Thus, when the filters 80 are later analyzed the analysis can becorrelated with the measurements acquired contemporaneously by apparatus10. The collection time for each filter 80 can also be controlled by thecontroller either based on pre-set durations set by an operator, or inresponse to changes in emission rates as detected by other sensors inapparatus 10.

In some examples, the filters 80 may be TEDA (TriEthyleneDiAmine)impregnated activated charcoal filter cartridges for Iodine-131collection. Alternative filters, such as Carbon-14 and Tritium filtersmay also be used in other examples of apparatus 10. In differentexamples, filters 80 may be housed within aluminum inline filter holdersor stainless steel cylinders. For example, the carbon-14 or tritiumfilters may be housed in stainless steel cylinders, while the Iodine-133filters may be housed in aluminum filter holders.

While tritium filters and carbon-14 filter may use similar housings, thefilter material may be different. Tritium filters may include molecularsieve (MS) 3 Å beads, while the carbon-14 traps may contain molecularsieve 4 Å. In some cases, the tritium and carbon-14 filters may besampled in sequence. As the filter materials are different, placing thetritium filters before the carbon-14 filters may not affect thecollection of carbon-14 due to the different filter materials used. As aresult, in some examples tritium filters could be employed in firstfilter trap 20, while carbon-14 filters are employed in second filtertrap 22.

Referring now to FIG. 7, shown therein is a schematic diagram of aportable detection apparatus 140. The schematic diagram illustrates thefluid flowpath or sample line traversed by a fluid in portable detectionapparatus 140. Portable detection apparatus 140 may be an example ofportable monitoring apparatus 10.

Apparatus 140 includes an apparatus inlet 142. Apparatus inlet 142 is afluid inlet used to draw a stream of fluid into apparatus 140. Apparatusinlet 142 is fluidly connected to a fluid conduit 144. Fluid conduit 144may be contained within a primary housing 188.

Fluid conduit 144 passes by, and is engaged by, gamma spectrometer 146.Gamma spectrometer 146 may include at least one sample channel 148 thatis sized to removably receive a portion of fluid conduit 144. Gammaspectrometer 146 may be used to detect radiation in stream of fluidpassing through fluid conduit 144 as described above. In general, gammaspectrometer 146 may be similar to gamma spectrometer 76 describedabove.

After passing through sample channel 148, fluid conduit 144 may entermercury analyzer 150. Mercury analyzer 150 may also analyze the fluidpassing through fluid conduit 144. Mercury analyzer 150 may be generallysimilar to mercury analyzer 72 described above.

After passing through mercury analyzer 150, the fluid flowpath may exitprimary housing 188 at fluid conduit outlet 154. After exiting primaryhousing 188, the fluid flowpath may be fluidly connected to first filtertrap 162. Primary housing 188 may also include a relief valve 156fluidly connected to fluid conduit 144. Relief valve 156 may beconfigured to relief an over-pressure situation by discharge the fluidfrom fluid conduit 144 using relief outlet 160. For example, if a valveassembly of first filter trap 162 fails an over-pressure situation mayarise, and relief valve 156 may discharge. A filter 158 may be used tofilter contaminants from the fluid discharged by relief valve 156.

First filter trap 162 includes a first valve assembly 168 and at least afirst filter 172 and a second filter 174. First filter trap 162 may begenerally similar in construction and operation to first filter trap 20described above. First valve assembly 168 is coupled to a controller166. Controller 166 may control the operation of first valve assembly168, thereby controlling the path of the fluid through apparatus 140.Controller 166 may be coupled to power source 190. In some examples,controllers 166 and power sources 190 may be contained within primaryhousing 12/188 (not shown). First filter trap 162 has a first filtertrap outlet 180.

First filter trap 162 is connected in series with second filter trap164. Second filter trap 164 includes a second valve assembly 170 and atleast a third filter 176 and a fourth filter 178. Second filter trap 164may be generally similar in construction and operation to second filtertrap 22 described above. Again, second filter trap 164 is coupled tocontroller 166 which may control the operation of second valve assembly170. Second filter trap 164 has a second filter trap outlet 182.

Second filter trap outlet 182 and first filter trap outlet 180 are bothfluidly connected to filter housing outlet 184. Filter housing outlet184 is in term fluidly connected to apparatus fluid outlet 186. When thestream of fluid passes through primary housing 188, the stream passesthrough at least one of the filters in the first filter trap 162 or thesecond filter trap 164, and then out the corresponding filter trapoutlet to filter housing outlet 184 and then to apparatus fluid outlet186 where it is discharged.

In some examples (not shown), the stream of fluid may pass through onefilter in the first filter trap 162 and then another filter in thesecond filter trap 164. This may occur when the first filter trap 162employs a different filter type from the second filter trap 164. Forexample, first filter trap 162 may employ tritium filters such as thosementioned above, and second filter trap 164 may employ carbon-14filters. Placing the tritium filters before the carbon-14 filters maynot affect the collection of carbon-14 due to the different filtermaterials used.

Referring now to FIG. 8, shown therein is a cross-section of a radiationshield 202 that may be used in some examples of portable detectionapparatus 10. Radiation shield 202 may be an example of radiation shield92 discussed above.

In the illustrated example the radiation shield 202 is configured torest on top of a gamma spectrometer such as gamma spectrometer 76.Radiation shield 202 may be an iron shield to shield the gammaspectrometer and sampling line from gamma and x-ray radiation andimprove the detection limit of gamma spectrometer. In some examples,radiation shield 202 may have a thickness of greater than 1.2 cm.Radiation shield 202 may have a half value layer (HVL) for gamma andx-ray radiations of 1.170 cm. In such examples, radiation shield 202 mayblock half of the energy of 0.55 MeV.

Radiation shield 202 may also be used to secure a sample channel orsampling jar in place while the gamma spectrometer is sampling.Generally, radiation shield 202 may be operated in two configurations(both of which are overlaid in FIG. 8. In a first configuration,radiation shield 202 houses a sampling jar 204. Sampling jar 204 may beused to collect air, soil, sediment, or water. Sampling jar 204 may thenbe placed under radiation shield 202 to permit in-field measurements bythe gamma spectrometer. Radiation shield 202 may hold sampling jar 204in place on top of the collimator of the gamma spectrometer. Radiationshield 202 may include a handle 212 to permit an operator to removeradiation shield 202 when changing operational configurations.

In a second configuration, radiation shield 202 holds a sample channel208 in place on top of the collimator of the gamma spectrometer.Radiation shield 202 may include a passage 210 to allow tubing 206 topenetrate into the core of the field without the walls of tubing 206being compressed. Passage 210 also holds tubing 206 in place duringsampling by the gamma spectrometer.

Tubing 206 may be coupled to a sample channel 208. Tubing 206 may enablesample channel 208 to receive a portion of the fluid conduit of theportable detection apparatus. This allows the fluid flowing through thefluid flowpath to be analyzed by the gamma spectrometer. Radiationshield 202 also reduces interference from background radiation duringsampling.

Referring now to FIG. 9, shown therein is an example process 300 formonitoring fluid contaminations. Process 300 is an example process thatmay be implemented using components of portable detection apparatus 10.Process 300 may also include fewer or greater steps for monitoring fluidcontaminations (beyond those shown in FIG. 9) such as those discussedabove.

Process 300 begins at 302 by drawing a stream of fluid into a fluidflowpath. For instance, the stream of fluid may be acquired using asample line such as apparatus fluid inlet 30. In some cases a pump maybe used to circulate the fluid within the fluid flowpath. As mentionedabove, in some examples the pump may be integral with mercury analyzer72, while in other examples a separate pump may be used.

At 304, the flowing fluid captured at 302 can be analyzed using aflow-through detection apparatus. The flow-through detection apparatusmay be used to detect radiation or mercury levels in the flowing fluid.For example, the detection apparatus may include a gamma spectrometersuch as gamma spectrometers 76 and 146 and/or a mercury analyzer such asmercury analyzers 72 and 150. Various other flow-through detectors mayalso be used, either alone or in combination in the flow-throughdetection apparatus.

At 306, a first batch of particulates or gaseous constituents can becaptured from the fluid using a first filter. The batch may be capturedby directing at least a portion of the fluid exiting the flow-throughdetection apparatus to flow through the first filter. The first filtermay be similar to one of the filters 80 mentioned above. The fluid maybe directed to flow through the first filter using a valve assembly asdiscussed above. The valve positions of the valve assembly may becontroller by a controller, and the valve positions may be stored overtime to ensure that analysis of the filters can be correlated with theanalysis performed by the flow-through detection apparatus at 304.

At 308, the first filter can be isolated from the fluid flowpath. Thefirst filter may be isolated by adjusting the valve positions of thevalve assembly coupled to the first filter. The first filter may beisolated from the fluid flowpath after it has collected particulatesfrom the fluid for a pre-defined sampling period. In some cases, oncethe first filter has been isolated from the fluid flowpath, it can bedetached from the fluid flowpath to allow for analysis of the capturedparticulate or to allow a new filter to be used in its place.

At 310, a second batch of particulates can be captures from the fluidwith a second filter. The second batch may be captured by directing theat least a portion of the fluid exiting the flow-through detectionapparatus to flow through a second filter. Again, the fluid may bedirected by adjusting a valve assembly coupled to the second filter.

The second filter may then sample the fluid for a second pre-definedperiod before it is also isolated from the fluid flowpath. Sampling thefluid using a sequence of filters over different time periods mayprovide discrete samples of how much particulate was released in eachtime period. This may allow for changes in the emission rate to bedetected. The particulate levels may be provided to the controller foruse along with the measurements performed by the flow-through detectionapparatus.

Based on the data collected by the controller, a plume profile may begenerated. The plume profile dynamically simulates emission plumes basedon wind and other environmental conditions. Wind conditions may bemeasured using a meteorological station such as weather station 74 orother weather stations positioned in the vicinity of the emission sourceor suspected emission source.

A user may select a date and time for the initial emission. Thecontroller can then identify the relevant meteorological data for theemission. The controller generates a puff model that simulates therelease of a series of gaseous spheres. Each sphere represents theamount of material that is issued from the source in a given timeperiod. Each sphere may be generated based on the measurements acquiredby apparatus 10. In the plume profile model, each individual sphereresponds to the wind direction and speed independently of any otherissued spheres. Each sphere dissipates in a Gaussian fashion as it ages,regardless of its position. If the wind changes speed or direction, thespheres respond in kind. Multiple sources may be profiled by duplicatingeach sphere of the primary source, scaled to the intensity, anddisplaced from the primary by a known distance.

The controller may generate an activity averaged plume over any timeperiod. This activity averaged plume can be used to determine theconcentration of a gaseous constituent at any point in the time period.Once a plume has been generated or modelled, the controller candetermine the emission rate from a known or suspected source based onthe measured concentration at a sampling point downwind of the source.The emission rate may be determined by setting an arbitrary emissionrate. The controller can then generate a modelled concentration at thesampling point based on the plume profile generated. Using a ratio ofthe modelled concentration (based on the arbitrary/modelled emissionrate) to the measured concentration, the actual emission rate at thesource can be determined. The ratio may take the form of:

$\frac{{modelled}\mspace{20mu}{emission}\mspace{14mu}{rate}}{{measured}\mspace{14mu}{emission}\mspace{14mu}{rate}} = \frac{{modelled}\mspace{14mu}{concentration}}{{measured}\mspace{14mu}{concentration}}$

What has been described above has been intended to be illustrative ofthe invention and non-limiting and it will be understood by personsskilled in the art that other variants and modifications may be madewithout departing from the scope of the invention as defined in theclaims appended hereto. The scope of the claims should not be limited bythe preferred embodiments and examples, but should be given the broadestinterpretation consistent with the description as a whole.

The invention claimed is:
 1. A portable detection apparatus comprising:a) an apparatus fluid inlet to draw in a stream of fluid, an apparatusfluid outlet and a fluid flowpath extending therebetween; b) a pump forcirculating the fluid through the fluid flowpath; c) at least oneflow-through detection apparatus configured to analyze the fluid as itis flowing through the fluid flowpath; and d) at least a first filtertrap provided in the fluid flowpath downstream from the at least oneflow-through detection apparatus, the first filter trap configured tocapture a first batch of particulates from the stream of fluid bydirecting at least a portion of the fluid exiting the at least oneflow-through detection apparatus to flow through a first filter, whereinthe first filter trap comprises a first valve assembly and a secondfilter, the first valve assembly configurable in a first configuration,in which the first filter is fluidly connected to the fluid flowpath anda second configuration in which the first filter is isolated from thefluid flowpath and the second filter is fluidly connected to the fluidflow path to capture a second batch of particulates from the stream offluid.
 2. The apparatus of claim 1, wherein the fluid flowpath comprisesa fluid conduit having a conduit inlet and a conduit outlet downstreamfrom the conduit inlet, and at least one flow-through detectionapparatus is between the conduit inlet and the conduit outlet and thefirst filter trap is between the conduit outlet and the apparatus fluidoutlet.
 3. The apparatus of claim 2, wherein the at least oneflow-through detection apparatus comprises a first sample channel thatis sized to removably receive a portion of the fluid conduit, andwherein the at least one flow-through detection apparatus is operable toanalyze the fluid while the fluid is flowing through the first samplechannel.
 4. The apparatus of claim 1, wherein the at least oneflow-through detection apparatus is configured to detect ionizingradiation emitted by the fluid while the fluid is flowing through thefluid flowpath and further comprising a radiation shield at leastpartially covering the at least one flow-through detection apparatus andthe sample channel to shield the portion of the fluid conduit receivedwithin the sample channel from background radiation.
 5. The apparatus ofclaim 1, wherein the first valve assembly comprises a first manifoldhaving a first manifold inlet connectable in fluid communication withthe filter housing fluid inlet, a first manifold outlet having a firstvalve and a second manifold outlet having a second valve, and whereinthe first filter is connectable to the first manifold outlet and thesecond filter is connectable to the second manifold outlet.
 6. Theapparatus of claim 5, wherein the first valve and second valve areoperable independently of each other.
 7. The apparatus of claim 1,further comprising at least two wheels rollingly supporting the portabledetection apparatus and a coupling for connecting the portable detectionapparatus to a vehicle and wherein the portable detection apparatuscomprises a width in a first direction and a length in a seconddirection that is orthogonal to the first direction, and wherein thewidth and length are each less than about 5 feet.
 8. The apparatus ofclaim 1, a second filter trap in the fluid flowpath downstream from theat least one flow-through detection apparatus, the second filter trapcomprising a second valve assembly and at least a third filter and afourth filter configured for capturing particulates from the stream offluid and removably connected to the second valve assembly, the secondvalve assembly configurable in a first configuration, in which the thirdfilter is fluidly connected to the fluid flowpath and the fourth filteris fluidly isolated from the fluid flowpath, and a second configuration,in which the fourth filter is fluidly connected to the fluid flowpathand the third filter is fluidly isolated from the fluid flowpath.
 9. Theapparatus of claim 8, a primary housing containing the at least oneflow-through detection apparatus, a first filter housing containing thefirst filter trap and a second filter housing containing the secondfilter trap, wherein the first filter housing and second filter housingare external to the primary housing and are detachably mounted to theprimary housing.
 10. The apparatus of claim 9, wherein the second filtertrap is fluidly connected in parallel with the first filter trap wherebyone of the first filter housing and the second filter housing can bedetached from the primary housing without interrupting the fluidcommunication between the other of the first filter housing and thesecond filter housing and the primary housing.
 11. The apparatus ofclaim 1, further comprising at least one onboard power sourceelectrically connected to at least one flow-through detection apparatusand filter trap.
 12. A portable detection apparatus comprising: a) anapparatus fluid inlet to draw in a stream of fluid, an apparatus fluidoutlet and a fluid flowpath extending therebetween; b) a pump forcirculating the fluid through the fluid flowpath; c) at least oneflow-through detection apparatus configured to analyze the fluid as itis flowing through the fluid flowpath; d) at least a first filter trapprovided in the fluid flowpath downstream from the at least oneflow-through detection apparatus, the first filter trap configured tocapture a first batch of particulates from the stream of fluid bydirecting at least a portion of the fluid exiting the at least oneflow-through detection apparatus to flow through a first filter; e) aprimary housing containing the at least one flow-through detectionapparatus, and a filter housing that is external the primary housing andcontains the first filter trap.
 13. The apparatus of claim 12, whereinthe apparatus fluid inlet is external and spaced apart from the primaryhousing by a distance of between about 1 m and 30m.
 14. The apparatus ofclaim 12, wherein the primary housing comprises the apparatus fluidinlet and the filter housing comprises the apparatus fluid outlet andwherein the primary housing comprises a primary housing fluid outletthat forms part of the fluid flowpath and the filter housing comprises afilter housing fluid inlet that forms part of the fluid flowpath andthat is detachably fluidly connectable to the primary housing fluidoutlet by a fluid coupling.
 15. The apparatus of claim 14, wherein thefilter housing is detachably mounted to the primary housing and whereinwhen the filter housing fluid inlet is detached from the primary housingfluid outlet the filter housing is detachable from the primary housing.16. The apparatus of claim 14, wherein the primary housing has a doorthat is movable between a closed position, in which the primary housingis fluidly sealed with the exception of the apparatus fluid inlet andthe primary housing fluid outlet, and an open position, in which the atleast one flow-through detection apparatus is accessible.
 17. Theapparatus of claim 16, wherein the filter housing has a body and lidthat is movable between a closed position and an open position, andwherein the first and second filters are removable when the lid is inthe open position, and wherein the lid is movable independently of thedoor on the primary housing.
 18. A portable detection apparatus fordetecting a targeted contaminant in the environment, the apparatuscomprising: a) a sample line configured to receive a flowing fluid froman environment; b) a detector positioned to detect a targetedcontaminant present in the fluid flowing through the sample line; c) acontroller linked to the detector and operable to trigger the detectorat a predetermined sampling rate while the fluid is flowing through thesample line; and d) at least a first filter trap provided in fluidcommunication downstream from sample line and the detector, the firstfilter trap configured to capture a first batch of particulates from thestream of fluid by directing at least a portion of the fluid exiting thesample line to flow through a first filter.